Toward the rational design of non-precious transition metal oxides for oxygen electrocatalysis

Author(s): Wesley T. Hong ¹ ^, ² ^, ³ ^, ⁴ , Marcel Risch ¹ ^, ² ^, ³ ^, ⁴ , Kelsey A. Stoerzinger ¹ ^, ² ^, ³ ^, ⁴ , Alexis Grimaud ¹ ^, ² ^, ³ ^, ⁴ , Jin Suntivich ⁵ ^, ⁶ ^, ⁷ ^, ⁴ , Yang Shao-Horn ¹ ^, ² ^, ³ ^, ⁴

Publication date (Electronic): 2015

Journal: Energy & Environmental Science

Publisher: Royal Society of Chemistry (RSC)

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Abstract

The rational design of non-precious transition metal perovskite oxide catalysts holds exceptional promise for understanding and mastering the kinetics of oxygen electrocatalysis instrumental to artificial photosynthesis, solar fuels, fuel cells, electrolyzers, and metal–air batteries.

Abstract

In this Review, we discuss the state-of-the-art understanding of non-precious transition metal oxides that catalyze the oxygen reduction and evolution reactions. Understanding and mastering the kinetics of oxygen electrocatalysis is instrumental to making use of photosynthesis, advancing solar fuels, fuel cells, electrolyzers, and metal–air batteries. We first present key insights, assumptions and limitations of well-known activity descriptors and reaction mechanisms in the past four decades. The turnover frequency of crystalline oxides as promising catalysts is also put into perspective with amorphous oxides and photosystem II. Particular attention is paid to electronic structure parameters that can potentially govern the adsorbate binding strength and thus provide simple rationales and design principles to predict new catalyst chemistries with enhanced activity. We share new perspective synthesizing mechanism and electronic descriptors developed from both molecular orbital and solid state band structure principles. We conclude with an outlook on the opportunities in future research within this rapidly developing field.

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A perovskite oxide optimized for oxygen evolution catalysis from molecular orbital principles.

Jin Suntivich, Kevin May, Hubert Gasteiger … (2011)

The efficiency of many energy storage technologies, such as rechargeable metal-air batteries and hydrogen production from water splitting, is limited by the slow kinetics of the oxygen evolution reaction (OER). We found that Ba(0.5)Sr(0.5)Co(0.8)Fe(0.2)O(3-δ) (BSCF) catalyzes the OER with intrinsic activity that is at least an order of magnitude higher than that of the state-of-the-art iridium oxide catalyst in alkaline media. The high activity of BSCF was predicted from a design principle established by systematic examination of more than 10 transition metal oxides, which showed that the intrinsic OER activity exhibits a volcano-shaped dependence on the occupancy of the 3d electron with an e(g) symmetry of surface transition metal cations in an oxide. The peak OER activity was predicted to be at an e(g) occupancy close to unity, with high covalency of transition metal-oxygen bonds.